Portable Electromagnetic Interference Shield

ABSTRACT

An electromagnetic interference shield having a main enclosure and optionally at least one auxiliary enclosure. The auxiliary enclosure and the main enclosure have an interior that is continuous with each other. The auxiliary enclosure is made of elastic Faraday material. The outer layer and inner layer may be transparent to view the electronic device. An auxiliary cable with filtering mechanisms may be provided inside a sleeve to allow access and transfer of data from the electronic device while still in the main enclosure.

CROSS-REFERENCE TO RELATED APPLICATION

This patent application is a continuation of U.S. patent applicationSer. No. 13/923,255, file on Jun. 20, 2013, entitled “PortableElectromagnetic Interference Shield with Flexible Cavity,” which is acontinuation-in-part of U.S. patent application Ser. No. 13/471,246,filed May 14, 2012, entitled “Portable Electromagnetic InterferenceShield,” which claims the benefit of U.S. Provisional Patent ApplicationNo. 61/486,124, entitled “Portable EMI Shield,” filed May 13, 2011. U.S.patent application Ser. No. 13/923,255 also claims the benefit of U.S.Provisional Patent Application No. 61/824,317, filed May 16, 2013,entitled “Portable Electromagnetic Interference Shield with FlexibleCavity.” Each of the foregoing applications are incorporated in theirentirety here by this reference.

A portion of the disclosure of this patent document contains materialwhich is subject to copyright protection. The copyright owner has noobjection to the facsimile reproduction by anyone of the patent documentor the patent disclosure, as it appears in the Patent and TrademarkOffice patent file or records, but otherwise reserves all copyrightrights whatsoever.

TECHNICAL FIELD

This invention relates generally to electromagnetic interference (EMI)enclosures, and more specifically relates to portable EMI enclosures foruse in shielding electronics from EMI and wireless communicationsignals.

BACKGROUND ART

EMI shields are useful for many purposes, specifically for protectingforensic evidence. If a portable wireless device is taken from its ownerit is important to ensure that the data on the device is not altered inany way from the point of seizure. One method of ensuring this is toshield the device from incoming or outgoing wireless signals using aportable EMI enclosure. It is often desirable to access the deviceinside of the EMI enclosure to forensically analyze the data it containswhile keeping the evidence shielded from EMI signals. It may also bedesirable to charge the device while inside of the EMI enclosure.

Prior to this invention, portable EMI enclosures did not provide amethod for maintaining EMI shielding while accessing the device insidevia cable for either data acquisition, charging, or both. Thus, there isa need for a method of accessing and connecting to a portable wirelessdevice via cable while it is inside of a portable EMI enclosure, withoutcompromising the shielding.

It is also desirable, or sometimes necessary, to manually operate adevice inside of a portable EMI enclosure. Portable wireless deviceswith touchscreens are particularly problematic to operate inside ofportable EMI enclosures. Thus, there is also a need for a method ofoperating portable wireless devices with touchscreens inside of portableEMI enclosures.

Portable EMI shields that allow one to preview devices contained thereinshield EMI signals less effectively than portable EMI enclosures that donot allow one to preview the devices contained inside. This is mostoften noticed when transporting wireless devices inside of EMIenclosures. The reason why this is most often noticed during transportis because it is at this time that a portable wireless device could comeclose to a signal tower. The closer a wireless device is to a signaltower, the better chance it will have of connecting with the signal fromthat tower, rendering the EMI enclosure useless.

EMI enclosures that allow access to a device within the enclosure andshield signals effectively exist but they are not portable. They areheavy, metal-lined enclosures as in U.S. Pat. No. 5,594,200 to Ramsey.

Many prior art portable EMI enclosures do not allow cable access to adevice inside without compromising their shielding. When operatedcorrectly, they are bags that become a sealed container as in U.S. Pat.No. 7,601,921 to Shroader.

Also, prior art portable EMI enclosures do not allow a human to operatea touchscreen device inside, and prior art portable EMI enclosures thatallow a preview of devices inside shield less effectively than portableEMI enclosures that do not allow preview.

Usage of touch screen devices inside of Faraday bags or other portableradio frequency shielding enclosures is difficult. The Faraday material(metalized fabric) is capacitive, therefore emulating the touch of afinger and contacting the device screen at multiple points. Solutionsexist that provide methods of usage, but they are generally notefficient.

For example, one device includes a block of foam surrounding a touchscreen device, which holds the Faraday material above the screen. Afinger is pushed into the center of the foam, against the Faradaymaterial, which contacts the screen at a single point. However, slidinga finger or another device across such an interface would be difficult.

In another device, a hard-sided RF shielding enclosure categorized as“non-portable” device is used. Although efficient, these methods arecumbersome. For example, a hard-sided RF shielding isolation box matedwith two gloves allows the user to place his hands inside of the gloves,and is able to operate a device inside of the box. However, the glovesare double-layered, and form-fitting to a hand. They are not efficientto use on touch screens due to the one-size-fits-all glove format, whichleaves loose fabric at fingertips for smaller hands. When extra fabricbunches at the fingertips, multiple points of contact are made on thedevice screen. The double layer of fabric adds to the problem byreducing the ability to accurately contact the screen.

In another device a user can place her hands inside of the Faraday boxthrough a sleeve. Sleeves formed from Faraday material contact theuser's arms directly. However, this system is not ideal as it offers thepotential for radio frequencies to enter the box when the user's armsare removed from the sleeves.

Furthermore, none of the existing devices address the ability to openand close the RF shielding device to insert or remove additional devicesto the shielding device without compromising an existing electronicdevice already in the shielding device. Current RF shielding enclosures,both portable and non-portable, are built with a single cavity. Devicesplaced inside of the cavity will no longer be shielded from signals whenthe cavity is reopened. This limits the ability of the operator to placeother devices inside of the cavity, such as a stylus to operate thedevice more effectively, a battery to provide auxiliary power, or aforensic product that can extract information from the device.

Finally, current RF shielding enclosures, both portable andnon-portable, are designed with a static form-factor. Non-portableenclosures are typically made with rigid materials, which are neitherflexible nor expandable. Portable enclosures typically have two or threesides, which may be flexible, but not expandable. If an irregularlyshaped object is placed inside of the enclosure, it may not fitcorrectly. Examples of these types of objects may be a phone with apower source connected to it, a router with antenna, or a tablet with abulky case.

DISCLOSURE OF INVENTION

The present invention relates to an EMI shield comprised of a mainenclosure and an auxiliary enclosure, both of which are properlyconstructed to shield an electronic device from EMI. The auxiliaryenclosure is made from elastic material that possesses shieldingproperties to prevent EMI from reaching an electronic device in the mainenclosure or auxiliary enclosure. In the preferred embodiment, theauxiliary enclosure is in the form of a pouch. The pouch configurationprovides a cost-effective design that is easy to use and provides themost versatility of features.

The auxiliary enclosure is also fastened to the main enclosure in a waythat prevents EMI from entering the main enclosure through the seamsused to attach the auxiliary enclosure to the main enclosure. In someembodiments, the auxiliary enclosure may be integrally formed with themain enclosure.

Both the main enclosure and the auxiliary enclosure are made of flexiblematerial to accommodate electronic devices of irregular shapes orparticularly large for bulky items.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1A is a perspective view of an embodiment of the EMI shieldaccording to the present invention.

FIG. 1B is the EMI shield in FIG. 1A with a portion of the protectivelayer and the shielding layer lifted up and/or removed for clarity.

FIG. 2A is a view of the back side of the sleeve of an EMI enclosureaccording of the present invention, the sleeve terminating with ametallic unit that may connect with the inner layer(s) of metalizedfabric as well as the outer layer(s) of protective fabric. The metallicunit may have a hole through it through which an auxiliary cable mayprotrude. As shown, a USB connection protrudes from the hole.

FIG. 2B is a view of the front side of the sleeve of an EMI enclosureaccording to the present invention with the metallic unit removed, thesleeve having a hole through which an end connection of an auxiliarycable protrudes. As shown, a USB connection protrudes from the hole.

FIG. 2C is a view of the front side of the sleeve of an EMI enclosureaccording to the present invention with a portion of a connectionremoved for clarity of the internal structure, the sleeve having a holethrough which an auxiliary cable may protrude. As shown, the auxiliarycable includes metalized shielding or an EMI filter which may be splicedat the end and connected with the metallic unit, which in turn contactsthe entire EMI enclosure.

FIG. 3A is a view of the front side of a portion of the embodiment ofthe EMI enclosure according to the present invention showing theauxiliary cable and filter unit outside of the EMI enclosure.

FIG. 3B is a view of the filter enclosure connected to an auxiliarycable that may be a component of the present invention.

FIG. 3C is a view of the filter enclosure wherein the metallic portionof an auxiliary cable connection is mated to the filter enclosure insuch a way that the device cable connection can become part of thecomplete EMI enclosure according to the present invention.

FIG. 3D is a view of small EMI filter that may be placed in between theend connection of a device cable and an auxiliary cable that runs insideof the sleeve of the enclosure according to the present invention.

FIG. 4A is a view of the inside of the main enclosure showing a filterenclosure according to the present invention.

FIG. 4B is the view of FIG. 4A with a device cable connected to thefilter enclosure.

FIG. 4C is a view of another embodiment of the inside of the mainenclosure showing a filter enclosure protruding from a hole without asleeve.

FIG. 4D is a view of the opposite end shown in FIG. 4C of the mainenclosure from the outside of the main enclosure.

FIG. 4E is a view of the EMI shielding enclosure showing a side with atransparent window, allowing preview of the contents of the enclosure.

FIG. 5 is a view of an embodiment of the EMI shield of the presentinvention showing an inner magnet and a stylus with a magnet on the endallowing a user to contact the touchscreen and activate it.

FIG. 6A is another embodiment of the enclosure in the closedconfiguration.

FIG. 6B is the enclosure of FIG. 6A in a partially closed figuration.

FIG. 6C is the embodiment of the enclosure shown in FIG. 6B in the openconfiguration.

FIG. 7 is a view of a cradle for holding and receiving a touchscreendevice inside of an EMI enclosure according to the present inventionthat prevents the metalized fabric from resting on the touchscreen ofthe device inside.

FIG. 8 is a view of the EMI shielding enclosure according to the presentinvention that shows an opening that can be closed or opened to allowdevices to enter or exit the enclosure.

FIG. 9 is a perspective view of an optional secondary EMI enclosurewithout a preview window in which an EMI enclosure according to thepresent invention may be placed, the EMI enclosure shown partiallyplaced inside the secondary EMI enclosure.

FIG. 10 is a perspective view of another embodiment of the presentinvention with portions cut away to show various features.

FIG. 11 is a top view of another embodiment of the present invention.

FIG. 12 is a partial perspective view of the embodiment of FIG. 11.

FIG. 13 is a cross-sectional view along line 13-13 in FIG. 11 while inuse.

FIG. 14 is a top view of the embodiment shown in FIG. 11 with anelectronic device isolated in an auxiliary enclosure.

FIG. 15 is a front perspective view of another embodiment of the presentinvention.

FIG. 16 is a rear perspective view of the embodiment shown in FIG. 15.

BEST MODE FOR CARRYING OUT THE INVENTION

The detailed description set forth below in connection with the appendeddrawings is intended as a description of presently-preferred embodimentsof the invention and is not intended to represent the only forms inwhich the present invention may be constructed or utilized. Thedescription sets forth the functions and the sequence of steps forconstructing and operating the invention in connection with theillustrated embodiments. However, it is to be understood that the sameor equivalent functions and sequences may be accomplished by differentembodiments that are also intended to be encompassed within the spiritand scope of the invention.

The present invention is a shielding device or EMI shield 100 to protectelectronic devices 10 from electromagnetic interference, radiofrequencyinterference, and any other wireless signals (generally referred to asEMI) that may interfere with, modify, or otherwise, compromiseinformation stored, received, or transmitted by an electronic device 10.The EMI shield 100 comprises a main enclosure 102 capable of fullycovering or enclosing the electronic device 10. In some embodiments, theEMI shield 100 may further comprise a means for accessing and connectingto the electronic device with an auxiliary cable 12. For example, themeans for accessing and connecting to the electronic device 10 with anauxiliary cable 12 may be a sleeve 104 connected to or integrally formedwith the enclosure 102. The sleeve may have a hole 106 or tunnel throughwhich the auxiliary cable 12 can be fed, or the hole 106 may be directlyon the enclosure 102 itself.

The enclosure 102 provides the shielding effect to the electronic device10. With reference to FIGS. 1A and 1B, the enclosure 102 may include anouter layer or protective layer 108 and an inner layer or shieldinglayer 110. The protective layer 108 provides protection to theelectronic device 10 as well as the shielding layer 110. In someembodiments, the protective layer 108 may be made of a durable, butflexible material such as canvas, nylon, leather, and the like. In someembodiments, the protective layer 108 may be made of a more sturdymaterial such as foam. In some embodiments, the protective layer 108 maybe made of a hard material such as metal or plastic. Therefore, in theembodiments utilizing sturdy or hard materials, the enclosure may havethe appearance of a box or a clamshell container, whereas the flexibleembodiments may be more like bags. However, the enclosure 102, whetherflexible, sturdy, or hard, can take on any shape, such as round, oval,triangular, rectangular, and the like.

In some embodiments, the enclosure 102 is made up of a durable fabricprotective layer 108, such as canvas having a generally rectangle shapewith two opposing surfaces 111, 113 defined by four sides 116, 118, 120,122 connected to each other to form four corners 124, 126, 128, 130. Theprotective layer 108 can be a single layer folded on top of itself andfastened at three of the four sides 118, 120, 122, with one side 116remaining unfastened so as to define an opening 131. The open side 116may comprise a fastening mechanism 133, such as a hook and loopfastener, zipper, adhesive, buttons, and the like so that the opening131 can be closed. In some embodiments, a strip of the hook portion 133a may be on the first surface 111 along the length of the top side 116,and a strip of the loop portion 133 b approximately the same length asthe loop portion 133 b may be on the second surface 113, but shiftedtowards the opposite side 120. The distance of the shift may be justover two widths of the strip so that when the strip of the hook portion133 a is folded over towards the second surface 113 twice, the strip ofthe hook portion 133 a mates with the strip of the loop portion 133 b.In some embodiments, the fastening mechanism 133 may be on the innersurface of the enclosure at the top side 116 so that the inner surfacesof the enclosure 102 are mated together. In some embodiments, thefastening mechanism 133 may be on the outer surface and the innersurface to provide a dual fastening system.

In some embodiments, two separate protective layers 108 may be fastenedtogether at three sides 118, 120, 122 to form the enclosure having anopening 131 at one side 116.

The shielding layer 110 may comprise one or more layers of a metalizedfabric, or other materials that can block EMI. The shielding layer 110may have an opening that can be closed or opened to allow electronicdevices to enter or exit the enclosure 102. Essentially, the shieldinglayer 110 lines the interior of the enclosure 102. In some embodiments,the shielding layer 110 may be loosely placed inside the enclosure 102.Therefore, the shielding layer 110 may simply be a pouch much like theenclosure 102, but slightly smaller to fit inside the enclosure 102. Insome embodiments, the shielding layer 110 may be stitched, glued, orotherwise fastened to the inner side of the enclosure 102. In thepreferred embodiment, to prevent any leaks or gaps in the shielding, theshielding layer 110 should be coextensive with the dimensions of theenclosure 102. In addition, the sealed sides 118, 120, 122 may be foldedover and sealed to create an overlap of the shielding layer 110 at thesides 118, 120, 122 to prevent any gaps.

To allow the electronic device 10 to be previewed or operated, a portionof one surface 111 of the enclosure 102 may have a transparent portionor window 112. This window 112 may be comprised of a transparentprotective layer made of a clear or see-through plastic, rubber,silicon, glass, and the like. In embodiments having a transparent window112, the shielding layer 110 must also have a transparent window ortransparent portion 114 overlapping with the transparent window 112 ofthe enclosure so that the transparent portion 114 permits the device 10to be seen while the transparent window 112 provides a protectivecovering for the transparent portion 114 of the shielding layer 110. Tocreate a portion of the shielding layer 110 that is transparent whilestill providing a shielding effect, the thread count of the metallizedfabric of the shielding layer 110 may be lowered relative to an opaqueshielding layer. The transparent window 112 or the transparent portion114 does not necessarily have to be completely transparent so long aselectronic device 10 is visible enough to operate while in the enclosure102.

To permit access to the electronic device 10 while still in theenclosure 102, the enclosure may have a hole 106. In some embodiments,the hole 106 may be operatively connected to a hollow sleeve 104. Thesleeve 104 may have the same construction as the enclosure 102, namely,the same or similar outer or protective layer 108 and the same orsimilar inner or shielding layer 110. An auxiliary cable 12 may beinserted through the sleeves 104 and/or the hole 106 to provide a meansfor connecting to the electronic device 10 inside the enclosure 102.

In the preferred embodiment, a sleeve 104 is operatively associated withthe enclosure 102 at one side 118 of the enclosure 102, essentiallyforming an extension or protrusion of side 118 and/or an extended edgeof one side 120 or corner 126 as shown in FIG. 1A. The sleeve 104 may beconnected to the sides 118 or the enclosure 102 or the sleeve 104 may beintegrally formed as a one-piece unit with the enclosure 102, extendingaway from the enclosure 102 and terminating at a free end 132. Thesleeve 104 can be associated with an enclosure 102 having any othershape.

The free end 132 of the sleeve 104 may comprise a metallic unit 134 thatmay connect with the shielding layer 110 of metalized fabric as well asthe protective layer 108 of material fabric. The metallic unit 134 atthe free end 132 of the sleeve 104 is described in further detail below.

Cable connections may also be included in the EMI shield 100. As shownin FIGS. 2A-2C, the metallic unit 134 at the free end 132 of the sleeve104 of the EMI enclosure 100 may include a hole 106 through which acable-end connection 16 of an auxiliary cable 12 protrudes. In theexample in FIGS. 2A-2C, a USB connection protrudes from the hole 106.The metallic portion of the cable-end 16 is mated to the metallic unit134 in such a way that the cable-end 16 can become part of the completeEMI enclosure 100. The auxiliary cable 12 includes metalized shieldingwhich may be spliced at the end and connected with the metallic unit134, which in turn contacts the entire EMI enclosure. As shown in FIGS.1B and 3A, the opposite end of the auxiliary cable 12 runs through thesleeve 104 towards the enclosure 102 and terminates at or near ajunction 136 where the sleeve 104 transitions to the enclosure 102.

In some embodiments, a connection 138 protruding from the metallic unit134 may be connected to the auxiliary cable 12 that is inside of thesleeve 104 of the enclosure 102. This auxiliary cable 12 includesmetalized shielding which may be spliced at the end and connected withthe connection 138, which in turn contacts the entire EMI enclosure. Insuch an embodiment, the metallic unit 134 may not be required.

In some embodiments, the auxiliary cable 12 may be configured with theaforementioned metallic unit 134 on one end, as well as a filterenclosure 140 on the opposite end. FIG. 3A shows the opposite end of theauxiliary cable 12 operatively connected to the filter enclosure 140 onthe outside of the sleeve 104. The filter enclosure 140 serves as aprotective covering for an EMI filter 142.

As shown in FIGS. 3A-3D, a small EMI filter 142 having a connectorportion 22 may be placed in between a connector end 18 of the devicecable 14 and the auxiliary cable 12 that runs inside of the sleeve 104,to prevent the auxiliary cable 12 from transmitting outside signal tothe electronic device 10 inside of the EMI shield 100. The EMI filter142 may be encased in a filter enclosure 140 that touches the shieldinglayer 110 of metalized fabric of the enclosure 102. The filter enclosure140 may be made of metal. The filter enclosure 140 may be connectablewith the opposite end of the auxiliary cable 12 that is not alreadyconnected to the metallic unit 134. Although FIG. 3D shows the auxiliarycable 12 soldered to the EMI filter 142, the connection may also beremovable, by adding another connector portion 24, such as a USBconnector, so that the auxiliary cable 12 can be removably connected tothe EMI filter 142 as shown in FIG. 4D.

The connector portion 18 of the device cable 14 is mated to the filterenclosure 140 in such a way that the cable connections can become partof the complete EMI shield 100. The connector portion 20 of the devicecable 14 opposite connector portion 18 can be connected to theelectronic device 10 inside the enclosure 102. Since these connectionsoccur inside of the EMI enclosure 102 the shielding is maintained. Theauxiliary cable 12 that extends from the filter enclosure 140 is alsoconnected to the metallic unit 134 on the free end 132 of the sleeve104. This metallic unit 134 has a cable end-connection 16 which isexternal to the EMI enclosure 102 and sleeve 104 and can be insertedinto another device. This configuration allows the electronic device 10placed inside of the EMI shield 100 to connect with devices outside ofthe EMI shield 100 while remaining shielded from EMI signals.

As shown in FIGS. 3A and 4A-4D, in the preferred embodiment, the EMIfilter 142 and filter enclosure 140 are positioned at the junction 136where the sleeve 104 transitions to the main enclosure 102. Inembodiments without the sleeve 104 the EMI filter 142 and filterenclosure 140 would be at the hole 106 of the main enclosure. Therefore,the filter enclosure 140 and/or the EMI filter 142 itself may befastened to the main enclosure 102 at the hole 106 with adhesives orother fastening methods so as to effectively seal the hole 106 as shownin FIGS. 4C and 4D. In such an embodiment, the EMI filter 142 may havetwo connector portions 22, 24 at each end instead of one. This allowsthe auxiliary cable 12 to be removable from the EMI filter 142.Therefore, a device 10 in the main enclosure will still be able tocommunicate or transmit data to an external device through an auxiliarycable 12 without a sleeve 104.

Manual operation of touchscreen devices inside of an EMI shield has beendifficult or impossible. One problem is that the electronic device 10cannot be seen when inside the enclosure 102. Another problem is thatthe user cannot touch the touchscreen 20 because it is inside theenclosure 102. A third problem is that when utilizing a flexiblematerial for the transparent windows 112, 114, the transparent portion114 of the shielding layer 110 will make contact with the touchscreen 20and possibly cause interference with actuation of the touchscreen 20.Therefore, a means for operating the electronic device from outside theenclosure and a means for preventing the shielding layer 110 fromtouching the touchscreen 20 of the electronic device 10 may be required.The visibility of the electronic device 10 has been obviated by thetransparent windows 112 and 114. A means for operating the electronicdevice from outside the enclosure and a means for preventing theshielding layer 110 from touching the touchscreen 20 of the electronicdevice 10 is described below.

In some embodiments, a means for operating the electronic device 10 fromoutside the enclosure may be provided, particularly where the electronicdevice 10 utilizes a touchscreen 20 as a method of input. For example,as shown in FIG. 5, one means for operating the electronic device 10from outside the enclosure 102 utilizes a magnet system. The magnetsystem may comprise an external magnet 144 used on the outside of theenclosure 102 and an internal magnet 146 used on the inside of theenclosure 102. The external magnet 144 may be used by the user tocontrol movement of the internal magnet 146 from outside the enclosure102. The internal magnet 146 makes contact with the electronic device10, particularly the touchscreen 20, and mimics a user's finger toactuate the touchscreen 20. The internal magnet 146 is placed inside ofthe EMI enclosure 102 before it is sealed.

To facilitate movement of the external magnet 144, the external magnet144 may be fixed to an elongated magnet holder 147. The elongated magnetholder 147 may be a pencil or pen-like device, such as a stylus. Usingthe stylus, with an external magnet 144 on the end, like a pen, the usercan move along the outside of the transparent window 112 near theinternal magnet 146 inside of the enclosure 102 to connect with theinternal magnet 146. Once the two magnets 144, 146 are connected, withthe transparent windows 112, 114 between the two magnets 144, 146, theinternal magnet 146 can be manipulated by the external magnet 144, whichis connected to the stylus. The internal magnet 146, which is of a sizesuitable for emulating finger touch, contacts the touchscreen 20 andactivates it. For example, the inner magnet 146 may be a disk magnet. Inthe preferred embodiment, the inner magnet 146 has a diameter ofapproximately 0.25 to approximately 0.5 inch and a thickness of 0.125inch. Most preferably, the inner magnet 146 has a diameter ofapproximately 0.375 inch. The shape and configuration also allows theinner magnet 146 to depress buttons on the electronic device 10. Theinner magnet 146 should also have smooth edges so as not to damage theelectronic device 10 or the shielding layer 110. Because hard drives userare-earth magnets, the inner magnet 146 should not affect the harddrives.

Preferably, the external magnet 144 of the elongated holder 147 is aspherical magnet with the pole aligned so that it is generally parallelwith to the elongated holder 147. The external magnet 144 may be, forexample, 0.25 inch in diameter. Preferably, both magnets are nickelplated neodymium magnets.

In some embodiments, a pocket 148 may be created on the transparentportion 114 of the shielding layer 110 or some other portion of theshielding layer 110 so that the internal magnet 146 can be “parked” orstored when not in use without interfering with the touchscreen 20. Thepocket 148 should be created on the side of the shielding layer 110adjacent to the device 10. However, the pocket 148 may be created inbetween the shielding layer 110 and the protective layer 108.

To further facilitate operating the device 10 in the enclosure 102, thecovering 112 a for the transparent portion 114 may be removable orseparable from the transparent portion 114 as shown in FIG. 6A. Forexample, the covering 112 a may be fastened to one of the sides 116,118, 120, or 122 of the enclosure 102. This allows the covering 112 athe lift up off of the surface of the transparent portion 114 of theshielding layer 110. By removing the covering 112 a off of thetransparent portion 114 of the shielding layer 110, actuation of theelectronic device 10 may be improved. In such an embodiment, thecovering 112 a does not necessarily have to be a transparent window.Thus, covering 112 a can be opaque.

A means for preventing the shielding layer 110 from touching thetouchscreen 20 of the electronic device 10 may be one or more firm,rigid, or semi-rigid structural supports 150 to separate the shieldinglayer 110 from the electronic device 10 and/or the touchscreen 20. Firmand rigid generally means that the structure can maintain its shape,structure, or configuration in its natural state regardless of how it isheld or positioned. For example, a sufficiently thick piece of foam,plastic, rubber, metal, wood, and the like will maintain their sameshape, structure, or configuration regardless of how they are positionedor held, whereas a rectangular piece of fabric would bend when held atthe corner and suspended in the air.

The structural support 150, for example, may be a piece of foam, rubber,plastic, metal, wood, glass, and the like. In the preferred embodiment,the support 150 is made of foam, rubber, or some other firm materialthat provides some cushioning effect. This prevents the enclosure 102from making contact with the screen of the electronic device 10. Inaddition, the support 150 prevents the means for operating theelectronic device from unintentionally operating the electronic device10. Finally, utilizing foam reduces the chance that the enclosure 102 orthe electronic device 10 will be damaged since the foam is lightweightand flexible.

In some embodiments, the support 150 may be a flexible material having afilling that provides structural firmness or rigidity. For example, thesupport 150 may be a plastic bag filled with air or water and sealedairtight. The structural support 150 can take on any shape so long asone overall dimension of the support 150, i.e. the height orcross-sectional diameter, is greater than the thickness T of theelectronic device 10. For example, the support 150 may be the shape of ablock, a ball, a pyramid, a dome, a cylinder, and the like. In thepreferred embodiment, the support 150 may be an elongated structurehaving a round, oval, square, rectangular, triangular, star-shaped, orany other shaped cross-sectional area, wherein one dimension D of thecross-sectional area is greater than the thickness T of the electronicdevice 10. Therefore, as shown in FIGS. 6B and 6C, when the electronicdevice 10 is laid flat in the enclosure 102, the support 150 extendsupwardly beyond the top surface or touchscreen of the electronic device10. Due to the firmness or rigidity of the support 150, the support 150pushes the shielding layer 110 away from the electronic device 10.

One or more structural supports 150 may be used. Preferably, multiplestructural supports 150 may be placed inside the enclosure 102 instrategic locations, for example, along one or more of the sides 116,118, 120, 122, as shown in FIGS. 6A and 6B. The electronic device 10 maybe placed in between these supports 150. The supports 150 can beindependent or individual pieces that can be inserted and removed fromthe enclosure 102. In some embodiments, supports 150 may be connectableto the enclosure 102, for example, with hook and loop fasteners,adhesives, and the like. In some embodiments, the supports 150 may beintegrally formed with the enclosure 102.

In some embodiments, multiple supports 150 a, 150 b may be arrangedtogether to form a cradle 160 as shown in FIG. 7. The cradle 160 may bea rigid or semi rigid support having a cavity 162 that receives theelectronic device 10. The cavity 162 may be defined by supports 150 a,150 b of the cradle 160 that have a height that is greater than thethickness T of the electronic device 10. Therefore, when the electronicdevice 10 is laid flat in the cavity 162 of the cradle 160, the supports150 a, 150 b extend upwardly beyond the top surface or touchscreen ofthe electronic device 10. The cradle 160 containing the electronicdevice 10 can be inserted into the enclosure 102. Due to the rigidity ofthe supports 150 a, 150 b, the shielding layer 110 is pushed away fromthe electronic device 10, like that shown in FIG. 6C. Bumpers 168 may beused to secure the electronic device 10 inside the cavity 162 bycreating a resistance fit between the electronic device 10 and thesupports 150 a, 150 b of the cradle 160, thereby providing addedprotection to the electronic device 10. Bumpers 168 may come in avariety of sizes that accommodate devices 10 of varying sizes.

The cradle 160 can be constructed in a variety of ways. For example, thecradle 160 may be constructed from foam, plastic, rubber, wood, glass,metal and the like. The cradle 160 can be a one-piece molded construct.Alternatively, the cradle 160 can be made of multiple pieces connectedtogether.

For additional shielding, the EMI enclosure 102 can be placed inside ofa secondary EMI enclosure 170 that may or may not have a transparentwindow (for example, for transport of the device 10 when it mayencounter strong EMI signals from signal towers nearby) as shown in FIG.9. Like enclosure 102, the secondary enclosure 170 has the same orsimilar protective layer 172 on the outside, preferably made of canvasor another durable material, and a shielding layer 174 of metalizedfabric on the inside. Shielding layer 174 of the secondary enclosure 170may be opaque and does not require a transparent window. One side of thesecondary enclosure 170 is an opening 176 in which devices can enter orexit the secondary enclosure 170. The side with the opening 176 maycomprise a closure system 178, such as a zipper, hook and loopfasteners, adhesives, buttons, and the like, similar to the mainenclosure 102. When the opening 176 is closed, the secondary enclosure170 is a fully sealed EMI enclosure without a preview window.

In some embodiments, as shown in FIG. 10, rather than utilizing aflexible fabric material for the enclosure 102, a firm, rigid, orsemi-rigid substrate 180 may be used. By way of example only, thesubstrate 180 may be made from a foam plastic. However, any other firm,rigid, or semi-rigid material can be used, such as wood, glass, metal,rubber, and the like. In the preferred embodiment, the substrate 180 maybe a foam plastic laminated to a conductive or metallic fabric 184 andmolded into the enclosure 182, having a construction design that allowsfor the overlap 185 of conductive fabric 184 at the seams and other,non-integral portions of the enclosure construction, such that when theenclosure 182 is closed properly it creates a signal-shielding ‘Faradaycage.’

The edges 186, 188, 190 of the laminated material 184 overlap to form acontinuous metallic surface around the contents of the enclosure 182,effectively shielding devices and other contents inside of the enclosure182 from incoming signals and preventing signals from the devices insidethe enclosure 182 from escaping the enclosure 182.

In addition to creating an aesthetically pleasing surface, thisconstruction produces a more durable conductive surface than conductivefabric alone due to the support of the laminated substrate 180. Thelaminated substrate 180 can be molded using heat and or compression toform the enclosure 182 which with appropriate design and overlappingseams, to eliminate the need to sew the conductive material 184, whichcan potentially damage it or weaken the protective property. Inaddition, the foam substrate enclosure 182 has many additional benefitssuch as allowing for joints or junctions 192 to be easily fastened tothe enclosure 182 through an orifice 200 with overlapping fabric whichwill maintain the Faraday integrity of the enclosure 182 while providingelectricity or data between a device inside of the enclosure 182 and adevice (such as a battery or a computer) outside of the enclosurewithout compromising the Faraday shielding property of the enclosure. Insome embodiments, a dividing wall 202 may be provided to create a secondcompartment to house batteries, cables, or other devices within theenclosure 182. The dividing wall 202 may have a slit or opening 204through which cables and the like can be inserted to connect with thedevice.

The foam substrate 180 also provides a level of physical protectionagainst bumping or crushing the devices 10 inside of the enclosure 182that current Faraday bags do not. The semi-rigid nature of the enclosure182 is lighter and more flexible than current metal boxes used toprovide Faraday shielding while providing more structure and form, andprotection to enclose devices 10 than bags which are currentlymanufactured out of conductive material for such purposes. An additionalbenefit to the fabric-plastic laminate construction is that the formedfoam substrate can suspend the conductive fabric on the inside of theenclosure 182 minimizing the contact of the fabric 184 to touch-screensurfaces 20 of devices 10 inside the enclosure 182. The suspension ofthe conductive fabric 184 off of the device 10 can allow making forbetter operation of a touchscreen 20 inside of the enclosure 182 bymeans of either pressing through the semi-rigid enclosure 182 with afinger or by the use of a stylus inside of the enclosure 182(manipulated with a magnet) without need of any additional frame orcradle inside the bag to suspend the fabric. A transparent orsemi-transparent conductive fabric 194 can be laminated to a transparentsubstrate (plastic or glass) material 196 to create a viewable windowthat, when properly installed with overlapping conductive fabric 194 atits seems will allow a device 10 to be viewed and manipulated within theenclosure 182 while maintaining an effective continuous Faraday shield.

These features should be considered novel when used in any combinationor order. The following describes possible uses of the presentinvention.

In one aspect, a portable wireless device 10 is seized, and device cable14 is connected to portable wireless device 10, and the other end of thedevice cable 14 already connected to portable wireless device isconnected to filter box 140 as shown in FIG. 4B. Then, a portablewireless device 10 is placed inside of EMI enclosure 102 and the EMIenclosure 102 is placed inside of transport bag 172. The EMI enclosure102 is removed from the transport bag 172, and a metallic unit 134 isinserted into data acquisition or charging device. As a result, thedevice 10 inside of EMI enclosure 102 interacts with externalacquisition or charging device through cable connection.

In another aspect, a portable touchscreen wireless device 10 is seized,and the portable touchscreen wireless device 10 is placed inside ofcradle 160. Then, a device cable 14 is connected to portable wirelessdevice and the other end of the device cable 14 is connected to filterbox 140. The portable wireless device 10 is placed inside of the EMIenclosure 102, and the EMI enclosure 102 is placed inside of transportbag 172. Next, the EMI enclosure 102 is removed from transport bag 172,a metallic unit 134 is inserted into data acquisition or chargingdevice, and the device 10 inside of EMI enclosure 102 interacts withexternal acquisition or charging device through cable connection. Thedevice 10 inside of EMI enclosure 102 can be human-operated by system ofmagnets 144, 146 and stylus 147.

In another aspect, a portable touchscreen wireless device 10 is seizedand the portable touchscreen wireless device 10 is placed inside ofcradle 160. A cable 14 is connected to the portable wireless device 10,and the other end of cable is connected to filter box 140. The portablewireless device 10 is placed inside of the EMI enclosure 102 and ametallic unit 134 is inserted into data acquisition or charging device.The device 10 inside of the EMI enclosure 102 interacts with externalacquisition or charging device through cable connection, and the deviceinside of EMI enclosure can be human-operated by system of magnets 144,146 and stylus 147.

In another embodiment, as shown in FIG. 11, the EMI shield 100 discussedabove may further comprise an auxiliary enclosure 1100 attached to themain enclosure 102, wherein the auxiliary enclosure 1100 has the same orsimilar shielding properties as the main enclosure 102. In the preferredembodiment, the auxiliary enclosure 1100 is made of an elastic Faradayfabric, such as the Technik-tex P 130+B made by Shieldex*. Preferably,the auxiliary enclosure 1100 is in the form of a pouch, and morepreferably, a fingerless pouch having one main cavity. Thus, the mainenclosure 102 may still comprise the outer or protective layer 108,inner or shielding layer 110 enveloped by the outer layer 108, and firstopening 116 to receive the electronic device 10 into the inner layer110. In addition, however, the main enclosure 102 may further comprise asecond opening 1102. The auxiliary enclosure 1100 may be attached to themain enclosure 102 at the second opening 1102. Since the auxiliaryenclosure 1100 has the same or similar shielding properties as the mainenclosure 102, in particular, the inner layer 110, an electronic device10 placed inside the main enclosure 102 is still protected fromelectromagnetic interference trying to enter through the second opening1102, due to the presence of the auxiliary enclosure 1100.

To maintain the integrity of the shielding effect, the auxiliaryenclosure 1100 is attached, by what is referred to as a shielded seam1111, to the main enclosure 102 at the second opening 1102 in a mannerthat prevents electromagnetic interference from entering through thesecond opening 1102. In the preferred embodiment, the shielded seam 1111is created on the inside of the main enclosure 102 so there issufficient overlap with the shielding layer 110 of the main enclosure102 to maintain the integrity of the shielding effect within theauxiliary enclosure 1100. Preferably, the auxiliary enclosure 1100 issewn into the main enclosure 102. However, other means of fastening theauxiliary enclosure 1100 to the main enclosure 102 can be used, such aswith adhesives, staples, and the like, so long as measures are taken sothat the magnetic interference cannot enter the main enclosure 102 orthe auxiliary enclosure 1100 through the seams. In some embodiments, theauxiliary enclosure 1100 may be integrally formed with the mainenclosure 102.

In the preferred embodiment, the second opening 1102 is created byseparating two adjacent edges 1104, 1106 of the main enclosure 102. Theseparation is then sealed with the auxiliary enclosure 1100. Combiningone-way or two-way stretch metalized fabric with non-elastic Faradayfabric is technically more difficult than sewing completely non-elasticfabric. When elastic Faraday fabric is stretched, shielding levels maybe reduced by up to 40%, depending on how much the material isstretched. To maintain the highest shielding, the fabric cannot bestretched during manufacture, which is a difficult task when sewingmultiple layers and adding seam binding 1112. The typical method is topull the fabric along with the seam binding 1112.

The method in the present application involves tacking the elasticFaraday fabric material first, to maintain position of the material andminimize stretching. To assure proper overlap, the portion of theauxiliary enclosure 1100 fastened to the main enclosure 102 is largerthan the second opening 1102, as shown in FIG. 12. A specific type ofconstruction ensures that all Faraday material terminations or junctionsin the auxiliary enclosure 1100 are overlapped and sewn with otherFaraday material in the main enclosure 102. If any terminations are leftopen, the shielding effectiveness of the bag will be reduced partiallyor completely. For example, the two outer edges 1108, 1110 of theauxiliary enclosure 1100 are sewn directly into the shielding layers 110of Faraday fabric in the main enclosure 102. The inner edges of theauxiliary enclosure are sewn into the two separate layers of Faradayfabric in the main enclosure 102. A first seam binding 1112 may coverthe inner edge 1113 of the auxiliary enclosure, but they shouldterminate slightly before the outer edges 1108, 1110 of the auxiliaryenclosure. This allows the seam bindings 1115 on the outer edges 1108,1110 to “squeeze” together and make contact with the two layers ofFaraday fabric in the main cavity, ensuring conductivity between alllayers.

Therefore, once properly sealed, the auxiliary enclosure 1100 basicallybecomes an extension of the main enclosure 102 while offering moreflexibility in accommodating larger or irregularly formed devices.Antennas on routers, for example, may impede placement of the router ina typical Faraday bag. The auxiliary enclosure 1100 provides a space forthe antenna to fit. In addition, the auxiliary enclosure 1100 may holdbatteries connected to devices, forensic products collected to phones,or any other irregularly shaped object.

With regards to the main enclosure 102, any of the features describedabove for the previous embodiments can be utilized with the embodimenthaving the auxiliary enclosure, such as the transparent windows 112,outer layer 108, inner layer 110 enveloped by the outer layer 108, afirst opening 116 to receive the electronic device into the inner layer110, and sleeve 104.

In use, once an electronic device 10 is placed in the main enclosure 102through the first opening 116, the first opening 116 can be sealed.However, the electronic device 10 can still be accessed and used withoutexposure to EMI by inserting the user's hand into the auxiliaryenclosure 1102 as shown in FIG. 12. To use the electronic device 10, auser can bunch the auxiliary enclosure 1100 into his hand, then inserthis hand with the auxiliary enclosure 1100 into the main enclosure 102while keeping the auxiliary enclosure 1102 taut as shown in FIG. 13. Bykeeping the auxiliary enclosure 1100 taut, the user can prevent loose orunintended portions of the auxiliary enclosure 1100 from touchingelectronic device 10. As the user continues to maneuver his hand towardselectronic device 10, if the auxiliary enclosure 1100 becomes too taut,the user can slowly release portions of the auxiliary enclosure 1100 toreach deeper into the main enclosure 102. Once the user reacheselectronic device 10, the user can perform an action on the electronicdevice 10 via the auxiliary enclosure 1100. For example, the user canextend one of his fingers to stretch a portion of the auxiliaryenclosure 1102 to maintain tautness. This tautness allows the user toperform the action on the electronic device 10 with the finger withoutcompromising the shielding and without allowing any other portion of theauxiliary pouch from touching the electronic device.

In another example, the user can grasp a secondary device 30 (such as astylus or pen) inside the main enclosure 102 with the auxiliaryenclosure 1100 while maintaining tautness of the auxiliary enclosure1100. The user can then perform the action on the electronic device 10with the secondary device 30 without compromising the shielding andwithout allowing any other portion of the auxiliary enclosure 1100 fromtouching the electronic device 10.

In another example, the user is able to add or remove additional devices30 from the main enclosure 102 while maintaining the shielded protectionof the electronic device 10 during the opening and closing of the mainenclosure 102. For example, the user may insert his hand into the mainenclosure 102 through the second opening 1102. The user can then graspthe electronic device 10 with the auxiliary enclosure 1100. The user canthen remove the electronic device 10 from the main enclosure 102 whilekeeping the electronic device 10 enveloped in the auxiliary enclosure1100 sufficiently to keep the electronic device 10 shielded. If desired,since the auxiliary enclosure 1100 is flexible, the user is able totwist the auxiliary enclosure 1100 at a point adjacent to the secondopening 1102 so as to seal the electronic device 10 within the auxiliaryenclosure 1100 irrespective of the main enclosure 102 as shown in FIG.14. Now, the user is able to add a secondary device 30 into the mainenclosure 102, or remove an existing secondary device 30 from the mainenclosure 102, without exposing the electronic device 10 to EMI. Oncethe secondary device 30 is added or removed, the user can close and sealthe first opening 116 as before. The auxiliary enclosure 1100 containingthe electronic device 110 can then be inserted back into the mainenclosure 102, and released from the auxiliary enclosure 1100.

The existence of an auxiliary enclosure 1100 offers more versatility inaccommodating large or irregular form factor devices inside the mainenclosure 102. In some embodiments, multiple auxiliary enclosures 1100may be attached to the main enclosure 102 in a manner similar to thatdiscussed above.

In another embodiment, the EMI shield may be in the form of a tent bag1500 as shown in FIGS. 15-16. The tent bag 1500, like the previousembodiments, may be a complete isolation bag with no USB line filtersleeve 104, or it may have an option for a USB line filter sleeve 104 asshown and described for the previous embodiments (e.g. FIG. 1A). Thisvariation provides an advantage over a traditional Faraday bag becausethe form factor allows larger devices (such as a laptop or table) to beplaced inside. The tent 1500 can be made of flexible shielding materialso that it can fold into a small flat or rolled up form.

In the preferred embodiment, the tent bag 1500 has a triangular shape,having a front side 1502, a back side 1504 opposite the front side 1502,a bottom side 1506 adjacent to the front 1502 and back side 1504, andtwo sides 1508, 1510, preferably having a triangular shape, oppositeeach other and adjacent to the front 1502, back 1504, and bottom side1506, thereby defining the main cavity 1501. Being triangular in shape,the front side 1502 and the back side 1504 are attached to each other atthe top 1512. However, other shapes can be used such as box shape,pentagon shapes, spherical shapes, and the like, and any combinationthereof.

All sides comprise the same shielding layer 110 material and aremanufactured in a similar way so as to assure that the interior of thetent bag 1500 is completely shielded from EMI as discussed in theprevious embodiments. The shielding layer 110 may also be covered by anouter layer 108, like the previous embodiments. The front side 1502 mayalso have a transparent portion 114 so that the electronic device 10inside the cavity 1501 of tent bag 1500 can be seen. This allows theuser to use the electronic device 10 inside the tent bag 1500 whilemaintaining the integrity of the shielding. In addition, the electronicdevices 10 can be photographed while being operated inside.

An opening 131 may be created at any intersection of any of the sides.Preferably, the opening 131 is created where the back side 1504 and thebottom side 1506 meet. A protective layer 108 with two opposing surfacelayers 111, 113 may be fastened to the tent bag 1500 with one layer 111attached to the back 1504 and the second layer 113 attached to thebottom side 1506. The two layers 111, 113 can be attached to each otheralong the two opposite 118, 122 sides leaving open side 116 to create apassage to the opening 131. The same fastening mechanism 133 asdiscussed in previous embodiments may be used to close the open side116. Therefore, a strip of the hook portion 133 a may be on the firstsurface 111 along the length of the first surface 111, but shifted awayfrom the open side 116, and a strip of the loop portion 133 bapproximately the same length as the hook portion 133 a may be on thesecond surface 113, but directly adjacent to the open side 116. Thedistance of the shift may be just over two widths of the strip of theloop portion 133 b so that when the strip of the loop portion 133 b isfolded over towards the first surface 111 twice, the strip of the loopportion 133 b mates with the strip of the hook portion 133 a. The stripof the hook portion 133 a and the loop portion 133 b can also bereversed. In essence the tent bag 1500 may be attached to a modifiedversion of the main enclosure 102 described for FIG. 1A-1B. Themodification would be in terms of its size, and the presence of anopening at one of the sides (e.g. side 120) so that there can be fluidcommunication from the opening 116 to the cavity 1501 of the tent bag1500.

In embodiments of the tent bag 1500 having the sleeve 104, the sleeve104 may be attached to the protective layer 108 at one of the sides 118,122 like the previous embodiments (e.g. FIG. 1A). Therefore, the sleeve104 may have the same or similar outer or protective layer 108 and thesame or similar inner or shielding layer 110. An auxiliary cable 12 maybe inserted through the sleeves 104 to provide a means for connecting tothe electronic device 10 inside the cavity 1501.

Of the two sides 1508, 1510, at least one side 1508 or 1510 andpreferably both sides 1508, 1510 are made of the elastic Faraday fabricused for the auxiliary enclosure 1100. This allows a user to operate ormanipulate devices 10 from one or two sides of the cavity 1501 with oneor both hands, if desired, similarly as described for the auxiliaryenclosure 1100 above. Therefore, like the embodiment with the auxiliaryenclosure 1100 discussed above, an electronic device 10 already insidethe main cavity 1501 can be temporarily removed while maintainingshielding by grasping the electronic device 10 with one of the sides1508 or 1510, and twisting the side to wrap up the electronic device 10.This allows the user to add or remove additional devices 30 through theprimary opening 116 or secondary opening 1520 without exposing theelectronic device 10 to any EMI. Therefore, the elastic sides 1508 or1510 are equivalent to the auxiliary enclosure 1100 and the cavity 1501is equivalent to the main enclosure 102. To ensure the integrity of theshielding effect, the two sides 1508, 1510 are attached to the frontside 1502, back side 1504, and bottom side 1506 using the same type ofoverlapping stitching technique as discussed above for the auxiliaryenclosure 1100.

In some embodiments, a frame 1530 may be provided to maintain the shapeof the tent bag 1500 in the open configuration. Removal of the frame1530 will allow the tent bag 1500 to be folded, rolled, or otherwisecollapsed into a convenient, transportable, or storable shape.

While the present invention has been described with regards toparticular embodiments, it is recognized that additional variations ofthe present invention may be devised without departing from theinventive concept. Antennas on routers, for example, may impedeplacement of the router in a typical Faraday bag or in Faradaycontainers having hard shell walls. Such portions of the electronicdevice that does not fit well in the main enclosure may protrude outthrough the auxiliary enclosure. The auxiliary enclosure may holdsecondary devices such as batteries connected to devices, forensicproducts connected to phones, or any other irregularly shaped objects.

INDUSTRIAL APPLICABILITY

This invention may be industrially applied to the development,manufacture, and use of EMI enclosures, and more specifically relates toportable EMI enclosures for use in shielding electronics from EMI andwireless communication signals.

What is claimed is:
 1. An electromagnetic interference (EMI) shield,comprising: (a) a flexible main enclosure to shield an electronic devicefrom electromagnetic interference, the main enclosure comprising: i. anouter layer; ii. an inner layer enveloped by the outer layer; iii. afirst opening to receive the electronic device into the inner layer; andiv. a second opening; and (b) an auxiliary enclosure attached to themain enclosure at the second opening.
 2. The EMI shield of claim 1,wherein the auxiliary enclosure is attached to the main enclosure with ashielded seam.
 3. The EMI shield of claim 1, wherein the auxiliaryenclosure is elastic.
 4. The EMI shield of claim 1, wherein theauxiliary enclosure is a fingerless pouch.
 5. The EMI shield of claim 1,wherein the main enclosure further comprises a hole through which theelectronic device can transmit data to an external device.
 6. The EMIshield of claim 1, wherein the inner layer comprises a transparentportion to view the electronic device inside.
 7. The EMI shield of claim1, wherein the main enclosure has a triangular cross-section defined bya front side, a back side opposite the front side, a bottom sideadjacent and attached to the front side and the back side, and two sidesopposite each other and attached to the front side, the back side, andthe bottom side, wherein one side is the auxiliary enclosure.
 8. The EMIshield of claim 7, where in the two sides are made of elastic Faradaymaterial.
 9. A method of using an electromagnetic interference (EMI)shield, comprising (a) being provided with the EMI shield, the EMIshield comprising a flexible main enclosure to shield the electronicdevice from electromagnetic interference; and an auxiliary pouchattached to the main enclosure, wherein the main enclosure comprises: i.an outer layer; ii. an inner layer enveloped by the outer layer; iii. afirst opening to receive the electronic device into the inner layer; andiv. a second opening through which the auxiliary pouch is attached tothe main enclosure; (b) placing the electronic device through the firstopening into the main enclosure of the EMI shield; and (c) sealing thefirst opening.
 10. The method of claim 9, further comprising: (a)bunching the auxiliary pouch into a user's hand; (b) inserting theuser's hand with the auxiliary pouch into the main enclosure whilekeeping the auxiliary pouch taut; (c) performing an action on theelectronic device via the auxiliary pouch.
 11. The method of claim 10,further comprising slowly releasing portions of the auxiliary pouch toreach deeper into the main enclosure.
 12. The method of claim 10,further comprising (a) extending a finger of the user to stretch aportion of the auxiliary pouch to maintain tautness; and (b) performingthe action on the electronic device with the finger without compromisingthe shielding and without allowing any other portion of the auxiliarypouch from touching the electronic device.
 13. The method of claim 10,further comprising: (a) grasping a secondary device inside the mainenclosure with the auxiliary pouch while maintaining tautness of theauxiliary pouch; and (b) performing the action on the electronic devicewith the secondary device without compromising the shielding and withoutallowing any other portion of the auxiliary pouch from touching theelectronic device.
 14. The method of claim 9, further comprising: (a)inserting a user's hand into the main enclosure through the secondopening; (b) grasping the electronic device with the auxiliary pouch;and (c) removing the electronic device from the main enclosure whilekeeping the electronic device enveloped in the auxiliary pouchsufficiently to keep the electronic device shielded from the mainenclosure.
 15. The method of claim 14, further comprising: (a) openingthe main enclosure at the first opening to insert or remove a seconddevice; (b) inserting or removing a second device into or from the mainenclosure, respectively; (c) closing and sealing the first opening; (d)inserting the auxiliary pouch back into the main enclosure; and (e)releasing the electronic device from the auxiliary pouch.
 16. Anelectromagnetic interference (EMI) shield, comprising: (a) a mainenclosure to shield an electronic device from electromagneticinterference, the enclosure, comprising: i. a protective layer having atransparent window, ii. a shielding layer having a transparent portionoverlapping the transparent window, iii. a first opening to receive theelectronic device, and iv. an orifice through which a device cableconnectable to the electronic device can exit; and (b) a sleeve having afirst end and a second end opposite the first end, the first end of thesleeve operatively associated with the enclosure for accessing andconnecting to the electronic device while the electronic device isinside the enclosure, without compromising shielding from theelectromagnetic interference, the sleeve, comprising an inner layer forshielding.
 17. The EMI shield of claim 16, further comprising anauxiliary enclosure attached to a second opening in the main enclosure,the auxiliary enclosure fastened to the main enclosure with a shieldedseam, the auxiliary enclosure made of a shielding material.
 18. The EMIshield of claim 17, where in the two sides are made of elastic Faradaymaterial.
 19. The EMI shield of claim 16, further comprising an EMIfilter connected to an auxiliary cable, wherein the auxiliary cable ishoused inside the sleeve.
 20. The EMI shield of claim 19, wherein theauxiliary cable comprises a first end and a second end, wherein the EMIfilter is connected to the auxiliary cable at the first end, and acable-end connection is attached to the auxiliary cable at a second end.